Estimation of background noise in audio signals

ABSTRACT

The disclosure relates to a background noise estimator and a method therein, for supporting sound activity detection in an audio signal segment. The method comprises reducing a current background noise estimate when the audio signal segment is determined to comprise music and the current background noise estimate exceeds a minimum value. This is to be performed when an energy level of an audio signal segment is more than a threshold higher than a long term minimum energy level, It_min, which is determined over a plurality of preceding audio signal segments, or, when the energy level of the audio signal segment is less than a threshold higher than It_min, but no pause is detected in the audio signal segment.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a Continuation Application of U.S. patentapplication Ser. No. 16/382,719, filed on Apr. 12, 2019, which is aContinuation Application of U.S. patent application Ser. No. 15/782,299,filed on Oct. 12, 2017, now U.S. Pat. No. 10,311,890, which is aContinuation Application of U.S. patent application Ser. No. 15/446,634,filed on Mar. 1, 2017, now U.S. Pat. No. 9,818,434, which is aContinuation Application of U.S. patent application Ser. No. 15/102,430,filed on Jun. 7, 2016, now U.S. Pat. No. 9,626,986, which is a 35 U.S.C.§ 371 national stage application of PCT International Application No.PCT/SE2014/051427, filed on Dec. 1, 2014, which itself claims thebenefit of U.S. Provisional Patent Application No. 61/918,258, filedDec. 19, 2013, the disclosures and contents of which are incorporated byreference herein in their entireties. The above-referenced PCTInternational Application was published in the English language asInternational Publication No. WO 2015/094083 A1 on Jun. 25, 2015.

TECHNICAL FIELD

The embodiments of the present disclosure relate to audio coding, and inparticular to estimation of background noise for supporting a soundactivity decision.

BACKGROUND

In communication systems utilizing discontinuous transmission (DTX) itis important to find a balance between efficiency and not reducingquality. In such systems an activity detector is used to indicate activesignals, e.g. speech or music, which are to be actively coded, andsegments with background signals which can be replaced with comfortnoise generated at the receiver side. If the activity detector is tooefficient in detecting non-activity, it will introduce clipping in theactive signal, which is then perceived as a subjective qualitydegradation when the clipped active segment is replaced with comfortnoise. At the same time, the efficiency of the DTX is reduced if theactivity detector is not efficient enough and classifies backgroundnoise segments as active and then actively encodes the background noiseinstead of entering a DTX mode with comfort noise. In most cases theclipping problem is considered worse.

FIG. 1 shows an overview block diagram of a generalized sound activitydetector, SAD or voice activity detector, VAD, which takes an audiosignal as input and produces an activity decision as output. The inputsignal is divided into data frames, i.e. audio signal segments of e.g.5-30 ms, depending on the implementation, and one activity decision perframe is produced as output.

A primary decision, “prim”, is made by the primary detector illustratedin FIG. 1. The primary decision is basically just a comparison of thefeatures of a current frame with background features, which areestimated from previous input frames. A difference between the featuresof the current frame and the background features which is larger than athreshold causes an active primary decision. The hangover addition blockis used to extend the primary decision based on past primary decisionsto form the final decision, “flag”. The reason for using hangover ismainly to reduce/remove the risk of mid and backend clipping of burst ofactivity. As indicated in the figure, an operation controller may adjustthe threshold(s) for the primary detector and the length of the hangoveraddition according to the characteristics of the input signal. Thebackground estimator block is used for estimating the background noisein the input signal. The background noise may also be referred to as“the background” or “the background feature” herein.

Estimation of the background feature can be done according to twobasically different principles, either by using the primary decision,i.e. with decision or decision metric feedback, which is indicated bydash-dotted line in FIG. 1, or by using some other characteristics ofthe input signal, i.e. without decision feedback. It is also possible touse combinations of the two strategies.

An example of a codec using decision feedback for background estimationis AMR-NB (Adaptive Multi-Rate Narrowband) and examples of codecs wheredecision feedback is not used are EVRC (Enhanced Variable Rate CODEC)and G.718.

There are a number of different signal features or characteristics thatcan be used, but one common feature utilized in VADs is the frequencycharacteristics of the input signal. A commonly used type of frequencycharacteristics is the sub-band frame energy, due to its low complexityand reliable operation in low SNR. It is therefore assumed that theinput signal is split into different frequency sub-bands and thebackground level is estimated for each of the sub-bands. In this way,one of the background noise features is the vector with the energyvalues for each sub-band. These are values that characterize thebackground noise in the input signal in the frequency domain.

To achieve tracking of the background noise, the actual background noiseestimate update can be made in at least three different ways. One way isto use an Auto Regressive, AR,-process per frequency bin to handle theupdate. Examples of such codecs are AMR-NB and G.718. Basically, forthis type of update, the step size of the update is proportional to theobserved difference between current input and the current backgroundestimate. Another way is to use multiplicative scaling of a currentestimate with the restriction that the estimate never can be bigger thanthe current input or smaller than a minimum value. This means that theestimate is increased each frame until it is higher than the currentinput. In that situation the current input is used as estimate. EVRC isan example of a codec using this technique for updating the backgroundestimate for the VAD function. Note that EVRC uses different backgroundestimates for VAD and noise suppression. It should be noted that a VADmay be used in other contexts than DTX. For example, in variable ratecodecs, such as EVRC, the VAD may be used as part of a rate determiningfunction.

A third way is to use a so-called minimum technique where the estimateis the minimum value during a sliding time window of prior frames. Thisbasically gives a minimum estimate which is scaled, using a compensationfactor, to get and approximate average estimate for stationary noise.

In high SNR cases, where the signal level of the active signal is muchhigher than the background signal, it may be quite easy to make adecision of whether an input audio signal is active or non-active.However, to separate active and non-active signals in low SNR cases, andin particular when the background is non-stationary or even similar tothe active signal in its characteristics, is very difficult.

SUMMARY

It would be desirable to make more adequate decisions of whether anaudio signal comprises active speech or music or not. Herein an improvedmethod for generating a background noise estimate is provided, whichenables a sound activity detector to make more adequate decisions.

According to a first aspect, a background noise estimation method isprovided, for supporting sound activity detection in an audio signalsegment. The method is intended to be performed by a background noiseestimator. The method comprises reducing a current background noiseestimate when the audio signal segment is determined to comprise musicand the current background noise estimate exceeds a minimum value. Thisis to be performed when an energy level of an audio signal segment ismore than a threshold higher than a long term minimum energy level,It_min, which is determined over a plurality of preceding audio signalsegments, or, when the energy level of the audio signal segment is lessthan a threshold higher than It_min, but no pause is detected in theaudio signal segment.

According to a second aspect, a background noise estimator is provided,for supporting sound detection in an audio signal segment. Thebackground noise estimator is configured to: when an energy level of anaudio signal segment is more than a threshold higher than a long termminimum energy level, It_min, or, when the energy level of the audiosignal segment is less than a threshold higher than It_min, but no pauseis detected in the audio signal segment: reduce a current backgroundnoise estimate when the audio signal segment is determined to comprisemusic and the current background noise estimate exceeds a minimum value.

According to a third aspect, a SAD is provided, which comprises abackground noise estimator according to the second aspect.

According to a fourth aspect, a codec is provided, which comprises abackground noise estimator according to the second aspect.

According to a fifth aspect, a communication device is provided, whichcomprises a background noise estimator according to the second aspect.

According to a sixth aspect, a network node is provided, which comprisesa background noise estimator according to the second aspect.

According to a seventh aspect, a computer program is provided,comprising instructions which, when executed on at least one processor,cause the at least one processor to carry out the method according tothe first aspect.

According to an eighth aspect, a carrier is provided, which contains acomputer program according to the seventh aspect.

BRIEF DESCRIPTION OF DRAWINGS

The foregoing and other objects, features, and advantages of thetechnology disclosed herein will be apparent from the following moreparticular description of embodiments as illustrated in the accompanyingdrawings. The drawings are not necessarily to scale, emphasis insteadbeing placed upon illustrating the principles of the technologydisclosed herein.

FIG. 1 is a block diagram illustrating an activity detector and hangoverdetermination logic.

FIG. 2 is a flow chart illustrating a background update decision logic,according to an exemplifying embodiment.

FIGS. 3 and 4 show a background estimator according to differentexemplifying embodiments.

FIG. 5 is a block diagram showing a sub-band energy backgroundestimator.

FIGS. 6-9 are diagrams showing how the embodiments allow for bettertracking of background noise in audio signals.

DETAILED DESCRIPTION

The solution disclosed herein relates to estimation of background noisein audio signals. In the generalized activity detector illustrated inFIG. 1, the function of estimating background noise is performed by theblock denoted “background estimator”. Some embodiments of the solutiondescribed herein may be seen in relation to solutions previouslydisclosed in WO2011/049514 and WO2011/049515, which are incorporatedherein by reference. The solution disclosed herein will be compared toimplementations of these previously disclosed applications. Even thoughthe solutions disclosed in WO2011/049514 and WO2011/049515 are goodsolutions, the solution presented herein still has advantages inrelation to these solutions. For example, the solution presented hereinhas an even less complex implementation and it is even more adequate inits tracking of background noise.

The performance of a VAD depends on the ability of the background noiseestimator to track the characteristics of the background—in particularwhen it comes to non-stationary backgrounds. With better tracking it ispossible to make the VAD more efficient without increasing the risk ofspeech clipping.

One problem with current noise estimation methods is that to achievegood tracking of the background noise in low SNR, a reliable pausedetector is needed. For speech only input, it is possible to utilize thesyllabic rate or the fact that a person cannot talk all the time to findpauses in the speech. Such solutions could involve that after asufficient time of not making background updates, the requirements forpause detection are “relaxed”, such that it is more probable to detect apause in the speech. This allows for responding to abrupt changes in thenoise characteristics or level. Some examples of such noise recoverylogics are: 1) As speech utterances contain segments with highcorrelation after a sufficient number of frames without correlation itis usually safe to assume that there is a pause in the speech. 2) Whenthe Signal to Noise Ratio, SNR>0, the speech energy is higher than thebackground noise, so if the frame energy is close to the minimum energyover a longer time, e.g. 1-5 seconds, it is also safe to assume that oneis in a speech pause. While the previous techniques work well withspeech only input they are not sufficient when music is considered anactive input. In music there can be long segments with low correlationthat still are music. Further, the dynamics of the energy in music canalso trigger false pause detection, which may result in unwanted,erroneous updates of the background noise estimate.

Ideally, an inverse function of an activity detector, or what would becalled a “pause occurrence detector”, would be needed for controllingthe noise estimation. This would ensure that the update of thebackground noise characteristics is done only when there is no activesignal in the current frame. However, as indicated above, it is not aneasy task to determine whether an audio signal segment comprises anactive signal or not.

Traditionally, when the active signal was known to be a speech signal,the activity detector was called Voice Activity Detector (VAD). The termVAD for activity detectors is often used also when the input signal maycomprise music. However, in modern codecs, it is also common to refer tothe activity detector as a Sound Activity Detector (SAD) when also musicis to be detected as an active signal.

The background estimator illustrated in FIG. 1 utilizes feedback fromthe primary detector and/or the hangover block to localize inactiveaudio signal segments. When developing the technology described herein,it has been a desire to remove, or at least reduce the dependency onsuch feedback. For the herein disclosed background estimation it hastherefore been identified by the inventors as important to be able tofind reliable features to identify the background signalscharacteristics when only an input signal with an unknown mixture ofactive and background signal is available. The inventors have furtherrealized that it cannot be assumed that the input signal starts with anoise segment, or even that the input signal is speech mixed with noise,as it may be that the active signal is music.

One contribution of the embodiments herein to the prior art is theselection of features to use, and even more, how to combine the selectedfeatures to achieve a noise estimation logic that works reliably fordifferent types of input.

As we have seen above, there are several features that work well forparticular conditions. The difficulty is to combine them in a way thatbenefits noise estimation and background tracking. In particular if oneis to avoid assumptions about initial conditions but rely only on thecharacteristics of the signal so far and be able to handle conditionswhere both speech and music are to be considered active inputs.

FIG. 2 is a flow chart illustrating an exemplifying embodiment of amethod for background noise estimation according to the herein proposedtechnology. The method is intended to be performed by a background noiseestimator, which may be part of a SAD. The background noise estimator,and the SAD, may further be comprised in an audio encoder, which may inits turn be comprised in a wireless device or a network node. For thedescribed background noise estimator, adjusting the noise estimate down,is not restricted. For each frame a possible new sub-band noise estimateis calculated, regardless if the frame is background or active content,if the new value is lower than the current it is used directly as itmost likely would be from a background frame. The following noiseestimation logic is a second step where it is decided if the sub-bandnoise estimate can be increased and if so how much, the increase isbased on the previously calculated possible new sub-band noise estimate.Basically this logic forms the decision of the current frame is abackground frame and if it is not sure it may allow a smaller increasecompared to what was originally estimated.

The method illustrated in FIG. 2 comprises: when an energy level of anaudio signal segment is more than a threshold higher 202:1 than a longterm minimum energy level, It_min, or, when the energy level of theaudio signal segment is less than a threshold higher 202:2 than It_min,but no pause is detected 204:1 in the audio signal segment:

-   reducing 206 a current background noise estimate when the audio    signal segment is determined 203:2 to comprise music and the current    background noise estimate exceeds a minimum value 205:1, denoted “T”    in FIG. 2, and further exemplified e.g. as 2*E_MIN in code below.

By performing the above, and providing the background noise estimate toa SAD, the SAD is enabled to perform more adequate sound activitydetection. Further, recovery from erroneous background noise estimateupdates is enabled.

The energy level of the audio signal segment used in the methoddescribed above may alternatively be referred to e.g. as the currentframe energy, Etot, or as the energy of the signal segment, or frame,which can be calculated by summing the sub-band energies for the currentsignal segment.

The other energy feature used in the method above, i.e. the long termminimum energy level, It_min, is an estimate, which is determined over aplurality of preceding audio signal segments or frames. It_min couldalternatively be denoted e.g. Etot_I_Ip One basic way of deriving It_minwould be to use the minimum value of the history of current frame energyover some number of past frames. If the value calculated as: “currentframe energy—long term minimum estimate” is below a threshold value,denoted e.g. THR1, the current frame energy is herein said to be closeto the long term minimum energy, or to be near the long term minimumenergy. That is, when (Etot—It_min)<THR1, the current frame energy,Etot, may be determined 202 to be near the long term minimum energyIt_min. The case when (Etot—It_min)=THR1 may be referred to either ofthe decisions, 202:1 or 202:2, depending on implementation. Thenumbering 202:1 in FIG. 2 indicates the decision that the current frameenergy is not near It_min, while 202:2 indicates the decision that thecurrent frame energy is near It_min. Other numbering in FIG. 2 on theform XXX:Y indicates corresponding decisions. The feature It_min will befurther described below.

The minimum value, which the current background noise estimate is toexceed, in order to be reduced, may be assumed to be zero or a smallpositive value. For example, as will be exemplified in code below, acurrent total energy of the background estimate, which may be denoted“totalNoise” and be determined e.g. as 10*log10 ΣZbackr[i], may berequired to exceed a minimum value of zero in order for the reduction tocome in question. Alternatively, or in addition, each entry in a vectorbackr[i] comprising the sub-band background estimates may be compared toa minimum value, E_MIN, in order for the reduction to be performed. Inthe code example below, E_MIN is a small positive value.

It should be noted that according to a preferred embodiment of thesolution suggested herein, the decision of whether the energy level ofthe audio signal segment is more than a threshold higher than It_min isbased only on information derived from the input audio signal, that is,it is not based on feedback from a sound activity detector decision.

The determining 204 of whether a current frame comprises a pause or notmay be performed in different ways based on one or more criteria. Apause criterion may also be referred to as a pause detector. A singlepause detector could be applied, or a combination of different pausedetectors. With a combination of pause detectors each can be used todetect pauses in different conditions. One indicator of that a currentframe may comprise a pause, or inactivity, is that a correlation featurefor the frame is low, and that a number of preceding frames also havehad low correlation features. If the current energy is close to the longterm minimum energy and a pause is detected, the background noise can beupdated according to the current input, as illustrated in FIG. 2. Apause may be considered to be detected when, in addition to that theenergy level of the audio signal segment is less than a threshold higherthan It_min: a predefined number of consecutive preceding audio signalsegments have been determined not to comprise an active signal and/or adynamic of the audio signal exceeds a threshold. This is alsoillustrated in the code example further below.

The reduction 206 of the background noise estimate enables handling ofsituations where the background noise estimate has become “too high”,i.e. in relation to a true background noise. This could also beexpressed e.g. as that the background noise estimate deviates from theactual background noise. A too high background noise estimate may leadto inadequate decisions by the SAD, where the current signal segment isdetermined to be inactive even though it comprises active speech ormusic. A reason for the background noise estimate becoming too high ise.g. erroneous or unwanted background noise updates in music, where thenoise estimation has mistaken music for background and allowed the noiseestimate to be increased. The disclosed method allows for such anerroneously updated background noise estimate to be adjusted e.g. when afollowing frame of the input signal is determined to comprise music.This adjustment is done by a forced reduction of the background noiseestimate, where the noise estimate is scaled down, even if the currentinput signal segment energy is higher than the current background noiseestimate, e.g. in a sub-band. It should be noted that the abovedescribed logic for background noise estimation is used to control theincrease of background sub-band energy. It is always allowed to lowerthe sub-band energy when the current frame sub-band energy is lower thanthe background noise estimate. This function is not explicitly shown inFIG. 2. Such a decrease usually has a fixed setting for the step size.However, the background noise estimate should only be allowed to beincreased in association with the decision logic according to the methoddescribed above. When a pause is detected, the energy and correlationfeatures may also be used for deciding 207 how large the adjustment stepsize for the background estimate increase should be before the actualbackground noise update is made.

As previously mentioned, some music segments can be difficult toseparate from background noise, due to that they are very noise like.Thus, the noise update logic may accidentally allow for increasedsub-band energy estimates, even though the input signal was an activesignal. This can cause problems as the noise estimate can become higherthan they should be.

In prior art background noise estimators, the sub-band energy estimatescould only be reduced when an input sub-band energy went below a currentnoise estimate. However, since some music segments can be difficult toseparate from background noise, due to that they are very noise like,the inventors have realized that a recovery strategy for music isneeded. In the embodiments described herein, such a recovery can be doneby forced noise estimate reduction when the input signal returns tomusic-like characteristics. That is, when the energy and pause logicdescribed above prevent, 202:1, 204:1, the noise estimation from beingincreased, it is tested 203 if the input is suspected to be music and ifso 203:2, the sub-band energies are reduced 206 by a small amount eachframe until the noise estimates reaches a lowest level 205:2.

The solution disclosed herein also relates to a background estimatorimplemented in hardware and/or software. A background estimator 500according to an exemplifying embodiment is schematically illustrated inFIG. 3. The background estimator 500 may be assumed to comprise an inputunit 502 for receiving energy measures and possibly correlationmeasures; and an output unit 505 for providing an updated backgroundnoise estimate. The background estimator 500 further comprises aprocessor 503 and a memory 504, said memory containing instructions 507executable by said processor 504. The execution of the instructions 507makes said background estimator 500 operative to perform at least oneembodiment of the method for background noise estimation describedabove. In other words, the execution of the instructions 507 by theprocessing means 503 makes the background estimator 500 operative to:when an energy level of an audio signal segment is more than a thresholdhigher than a long term minimum energy level, It_min, which isdetermined over a plurality of preceding audio signal segments, or, whenthe energy level of the audio signal segment is less than a thresholdhigher than It_min, but no pause is detected in the audio signalsegment: -reduce a current background noise estimate when the audiosignal segment is determined to comprise music and the currentbackground noise estimate exceeds a minimum value; The instructions 507may be stored in form of computer code, e.g. as the one presentedfurther below in this disclosure. The instructions or computer programmay be carried by a carrier before being stored and/or executed by thebackground estimator. Such a carrier may be e.g. an electronic signal,an optical signal, a radio signal, or, a computer readable storagemedium.

FIG. 4 shows an alternative implementation of a background estimator.The background estimator 400 comprises an input/output unit 401, energydetermining means 402 configured for determining whether the currentframe energy is close to a long term minimum energy estimate or not, apause detector 403, configured to determine whether a current framecomprises a pause, music detector, configured to determine whether acurrent frame comprises music or not. The background estimator 400further comprises a background estimator adjuster 405, configured to:when an energy level of an audio signal segment is more than a thresholdhigher than a long term minimum energy level, It_min, or, when theenergy level of the audio signal segment is less than a threshold higherthan It_min, but no pause is detected in the audio signal segment:-reduce a current background noise estimate when the audio signalsegment is determined to comprise music and the current background noiseestimate exceeds a minimum value. The background estimator adjuster 405may also be configured to perform e.g. a regular adjustment, as the oneillustrated as 208 in FIG. 3.

A background estimator as the ones described above can be comprised orimplemented in a VAD or SAD and/or in an encoder and/or a decoder,wherein the encoder and/or decoder can be implemented in a user device,such as a mobile phone, a laptop, a tablet, etc. The backgroundestimator could further be comprised in a network node, such as a MediaGateway, e.g. as part of a codec.

FIG. 5 is a block diagram schematically illustrating an implementationof a background estimator according to an exemplifying embodiment. Aninput framing block 51 first divides the input signal into frames ofsuitable length, e.g. 5-30 ms. For each frame, a feature extractor 52calculates at least the following features from the input: 1) Thefeature extractor analyzes the frame in the frequency domain and theenergy for a set of sub-bands are calculated. The sub-bands are the samesub-bands that are to be used for the background estimation. 2) Thefeature extractor further analyzes the frame in the time-domain andcalculates a correlation denoted e.g. cor_est and/or It_cor_est, whichis used in determining whether the frame comprises active content ornot. 3) The feature extractor further utilizes the current frame totalenergy, e.g. denoted Etot, for updating features for energy history ofcurrent and earlier input frames, such as the long term minimum energy,It_min. The correlation and energy features are then fed to the UpdateDecision Logic block 53.

Here, a decision logic according to the herein disclosed solution isimplemented in the Update Decision Logic block 53, where the correlationand energy features are used to form decisions on whether the currentframe energy is close to a long term minimum energy or not; on whetherthe current frame is part of a pause (not active signal) or not; andwhether the current frame is part of music or not. The solutionaccording to the embodiments described herein involves how thesefeatures and decisions are used to update the background noiseestimation in a robust way.

Below, some implementation details of embodiments of the solutiondisclosed herein will be described. The implementation details below aretaken from an embodiment in a G.718 based encoder. This embodiment usessome of the features described in WO2011/049514 and WO2011/049515, ofwhich parts are appended to this disclosure.

The following features are defined in the modified G.718 described inWO2011/09514:

Etot; The total energy for current input frame Etot_I Tracks themiminmum energy enevelope Etot_I_Ip; A Smoothed version of the mimimumenergy evnelope Etot_I totalNoise; The current total energy of thebackground estimate bckr[i]; The vector with the sub-band backgroundestimates tmpN[i]; A precalculated potential new background estimateaEn; A background detector which uses multiple features (a counter)harm_cor_cnt Counts the frames since the last frame with correlation orharmonic event act_pred A prediction of activity from input framefeatures only cor[i] Vector with correlation estimates for, i = 0 end ofcurrent frame, i = 1 start of current frame, i = 2 end of previous frame

The following features are defined in the modified G.718 described inWO2011/09515:

Etot_h Tracks the maximum energy envelope sign_dyn_Ip; A smoothed inputsignal dynamics

Also the feature Etot_v_h was defined in WO2011/049514, but in thisembodiment it has been modified and is now implemented as follows:

Etot_v = (float) fabs(*Etot_last - Etot); if( Etot_v < 7.0f)  /*notethat no VAD flag or similar is used here*/ {  *Etot_v_h -= 0.01f;  if(Etot_v > *Etot_v_h)  {   if ((*Etot_v -*Etot_v_h) > 0.2f)   {  *Etot_v_h = *Etot_v_h + 0.2f;   }   else   {    *Etot_v_h = Etot_v;}}}

Etot_v measures the absolute energy variation between frames, i.e. theabsolute value of the instantaneous energy variation between frames. Inthe example above, the energy variation between two frames is determinedto be “low” when the difference between the last and the current frameenergy is smaller than 7 units. This is utilized as an indicator of thatthe current frame (and the previous frame) may be part of a pause, i.e.comprise only background noise. However, such low variance couldalternatively be found e.g. in the middle of a speech burst. Thevariable Etot_last is the energy level of the previous frame.

The above steps described in code may be performed as part of the“calculate/update correlation and energy” steps in the flow chart inFIG. 2, i.e. as part of the actions 201. In the WO2011/049514implementation, a VAD flag was used to determine whether the currentaudio signal segment comprised background noise or not. The inventorshave realized that the dependency on feedback information may beproblematic. In the herein disclosed solution, the decision of whetherto update the background noise estimate or not is not dependent on a VAD(or SAD) decision.

Further, in the herein disclosed solution, the following features, whichare not part of the WO2011/049514 implementation, may becalculated/updated as part of the same steps, i.e. the calculate/updatecorrelation and energy steps illustrated in FIG. 2. These features arealso used in the decision logic of whether to update the backgroundestimate or not.

In order to achieve a more adequate background noise estimate, a numberof features are defined below. For example, the new correlation relatedfeatures cor_est and It cor_est are defined. The feature cor_est is anestimate of the correlation in the current frame, and cor_est is alsoused to produce It_cor_est, which is a smoothed long-term estimate ofthe correlation.

cor_est=(cor[0]+cor[1]+cor[2])/3.0f ;

st—>lt_cor_est=0.01f*cor_est+0.99f*st—>lt_cor_est;

As defined above, cor[i] is a vector comprising correlation estimates,and cor[0] represents the end of the current frame, cor[1] representsthe start of the current frame, and cor[2] represents the end of aprevious frame.

Further, a new feature, It_tn_track, is calculated, which gives a longterm estimate of how often the background estimates are close to thecurrent frame energy. When the current frame energy is close enough tothe current background estimate this is registered by a condition thatsignals (1/0) if the background is close or not. This signal is used toform the long-term measure It_tn_track.

st—>It_tn_track=0,03f*(Etot−st—>totalNoise<10)+0.97f*st—>It_tn_track;

In this example, 0,03 is added when the current frame energy is close tothe background noise estimate, and otherwise the only remaining term is0,97 times the previous value. In this example, “close” is defined asthat the difference between the current frame energy, Etot, and thebackground noise estimate, totalNoise, is less than 10 units. Otherdefinitions of “close” are also possible.

Further, the distance between the current background estimate, Etot, andthe current frame energy, totalNoise, is used for determining a feature,It_tn_dist, which gives a long term estimate of this distance. A similarfeature, It_ElIp_dist, is created for the distance between the long termminimum energy Etot_I_Ip and the current frame energy, Etot.

st—>It_tn_dist=0.03f*(Etot−st—>totalNoise)+0.97f*st—>It_tn_dist;

st—>It_ElIp_dist=0.03f*(Etot−st—>Etot_I_Ip)+0.97f*st—>It_ElIp_dist;

The feature harm_cor_cnt, introduced above, is used for counting thenumber of frames since the last frame having a correlation or a harmonicevent, i.e. since a frame fulfilling certain criteria related toactivity. That is, when the condition harm_cor_cnt==0, this implies thatthe current frame most likely is an active frame, as it showscorrelation or a harmonic event. This is used to form a long termsmoothed estimate, It_haco_ev, of how often such events occur. In thiscase the update is not symmetric, that is different time constants areused if the estimate is increased or decreased, as can be seen below.

if (st->harm_cor_cnt == 0)  /*when probably active*/ {  st->lt_haco_ev =0,03f + 0.97f*st->lt_haco_ev;  /*increase long term estimate*/ } else { st->lt_haco_ev = 0.99f*st->lt_haco_ev; /*decrease long term estimate */}

A low value of the feature It_tn_track, introduced above, indicates thatthe input frame energy has not been close to the background energy forsome frames. This is due to that It_to_track is decreased for each framewhere the current frame energy is not close to the background energyestimate. It_tn_track is increased only when the current frame energy isclose to the background energy estimate as shown above. To get a betterestimate of how long this “non-tracking”, i.e. the frame energy beingfar from the background estimate, has lasted, a counter,low_tn_track_cnt, for the number of frames with this absence of trackingis formed as:

if (st->lt_tn_track<0.05f)  /*when lt_tn_track is low */ { st->low_tn_track_cnt++;  /*add 1 to counter */ } else {  st->low_tn_track_cnt=0;  /*reset counter */ }

In the example above, “low” is defined as below the value 0.05. Thisshould be seen as exemplifying value, which could be selecteddifferently.

For the step “Form pause and music decisions” illustrated in FIG. 2, thefollowing three code expressions are used to form pause detection, alsodenoted background detection. In other embodiments and implementations,other criteria could also be added for pause detection. The actual musicdecision is formed in the code using correlation and energy features.

1: bg_bgd=Etot<Etot_I_Ip+0.6f*st—>Etot_v_h;

bg_bgd will become “1” or “true” when Etot is close to the backgroundnoise estimate. bg_bgd serves as a mask for other background detectors.That is, if bg_bgd is not “true”, the background detectors 2 and 3 belowdo not need to be evaluated. Etot_v_h is a noise variance estimate,which could alternatively be denoted N_(var). Etot_v_h is derived fromthe input total energy (in log domain) using Etot_v which measures theabsolute energy variation between frames. Note that the feature Etot_v_his limited to only increase a maximum of a small constant value, e.g.0.2 for each frame. Etot_I_Ip is a smoothed version of the mimimumenergy envelope Etot_I.

2: aE_bgd=st—>aEn==0;

When aEn is zero, aE_bgd becomes “1” or “true”. aEn is a counter whichis incremented when an active signal is determined to be present in acurrent frame, and decreased when the current frame is determined not tocomprise an active signal. aEn may not be incremented more than to acertain number, e.g. 6, and not be reduced to less than zero. After anumber of consecutive frames, e.g. 6, without an active signal, aEn willbe equal to zero.

3: sd1_bgd=(st—>sign_dyn_Ip>15)&& (Etot−st—>Etot_I_Ip)<st—>Etot_v_h &&st—>harm_cor_cnt>20;

Here, sd1_bgd will be “1” or “true” when three different conditions aretrue: The signal dynamics, sign_dyn_Ip is high, in this example morethan 15; The current frame energy is close to the background estimate;and: A certain number of frames have passed without correlation orharmonic events, in this example 20 frames.

The function of the bg_bgd is to be a flag for detecting that thecurrent frame energy is close to the long term minimum energy. Thelatter two, aE_bgd and sd1_bgd represent pause or background detectionin different conditions. aE_bgd is the most general detector of the two,while sd1_bgd mainly detects speech pauses in high SNR.

A new decision logic according to an embodiment of the technologydisclosed herein, is constructed as follows in code below. The decisionlogic comprises the masking condition bg_bgd, and the two pausedetectors aE_bgd and sd1_bgd. There could also be a third pausedetector, which evaluates the long term statistics for how well thetotalNoise tracks the minimum energy estimate. The conditions evaluatedif the first line is true is decision logic on how large the step sizeshould be, updt_step and the actual noise estimation update is theassignment of value to “st—>bckr[i]=—”. Note the tmpN[i] is a previouslycalculated potentially new noise level calculated according to thesolution described in WO2011/049514. The decision logic below followsthe part 209 of FIG. 2, which is partly indicated in connection with thecode below

if (bg_bgd && ( aE_bgd || sd1_bgd || st->lt_tn_track >0.90f ) ) /*if202:2 and 204:2)*/  {   if( (st->act_pred < 0.85f || ( aE_bgd &&st->lt_haco_ev < 0.05f) ) &&     (st->lt_Ellp_dist < 10 || sd1_bgd ) &&st->lt_tn_dist<40 &&     ( (Etot - st->totalNoise ) < 15.0f ||st->lt_haco_ev < 0.10f ) )  /*207*/   {    st->first_noise_updt = 1;   for( i=0; i< NB_BANDS; i++)    {     st->bckr[i] = tmpN[i)          /*208*/    }   }   else if (aE_bgd && st->lt_haco_ev < 0.15f)  {    updt_step=0.1f;    if (st->act_pred > 0.85f)    {     updt_step=0.01f           /*207*/    }    if (updt_step > 0.0f)   {     st->first_noise_updt = 1;     for[ i=0; i< NB_BANDS; i++)     {      st->bckr[i] = st->bckr[i] + updt_step * (tmpN[i]-st->bckr[i]);   /*208*/   }}}   else  {    (st->first_noise_updt) +=1;  } } else {   /* If in music lower bckr to drop further */ /*if 203:2 and 205:1*/   If ( st->low_tn_track_cnt > 300 && st->lt_haco_ev > 0.9f && st->totalNoise > 0.0f)    {     For ( i=0; i< NB_BANDS; i++)     {      If(st->bckr[i] > 2* E_MIN      {       St->bckr[i] = 0.98f * st->bckr[i];     /*206*/      }     }    }    Else    {     (st->first_noise_updt)+= 1;    } }

The code segment in the last code block starting with “/* If in music .. . */ contains the forced down scaling of the background estimate whichis used if it is suspected that the current input is music. This isdecided as a function: long period of poor tracking background noisecompared to the minimum energy estimate, AND, frequent occurrences ofharmonic or correlation events, AND, the last condition “totalNoise>0”is a check that the current total energy of the background estimate islarger than zero, which implies that a reduction of the backgroundestimate may be considered. Further, it is determined whether“bckr[i]>2*E_MIN”, where E_MIN is a small positive value. This is acheck of each entry in a vector comprising the sub-band backgroundestimates, such that an entry needs to exceed E_MIN in order to bereduced (in the example by being multiplied by 0,98). These checks aremade in order to avoid reducing the background estimates into too smallvalues.

The embodiments improve the background noise estimation which allowsimproved performance of the SAD/VAD to achieve high efficient DTXsolution and avoid the degradation in speech quality or music caused byclipping.

With the removal of the decision feedback described in WO2011/09514 fromthe Etot_v_h, there is a better separation between the noise estimationand the SAD. This has benefits as that the noise estimation is notchanged if/when the SAD function/tuning is changed. That is, thedetermining of a background noise estimate becomes independent of thefunction of the SAD. Also the tuning of the noise estimation logicbecomes easier as one is not affected by secondary effects from the SADwhen the background estimates are changed.

Below follows description of figures illustrating the problems solvedwith the embodiments disclosed herein.

FIG. 6 is a diagram showing the energy, Etot (dots) of a number offrames of an audio signal. The diagram shows the background estimatedwith prior art solution (lower, thinner curve, “x”), and estimatedaccording to an embodiment of the suggested solution (upper, thickercurve, “+”). This diagram shows how the embodiments allow for bettertracking of the background noise by keeping the total energy estimate ata higher level and by reacting quicker e.g. around frame 2510 comparedto 2610 for the original solution.

FIG. 7 is also a diagram showing the energy, Etot (dots) of a number offrames of an audio signal. The diagram shows the background estimatedwith prior art solution (lower, thinner curve, “x”), and estimatedaccording to an embodiment of the suggested solution (upper, thickercurve, “+”). It can be seen that the estimation according to the hereinsuggested solution tracks the background noise more efficiently, e.g.the background noise between the utterances, in particular in the framenumber range 1600-1700.

FIG. 8 is also a diagram showing the energy, Etot (dots) of a number offrames of an audio signal. The diagram shows the background estimatedwith prior art solution (more upper, thinner curve, “x”), and estimatedaccording to an embodiment of the suggested solution (more lower,thicker curve, “+”). The diagram shows the benefit of the suggestedsolution as compared to when the (prior art) tracking of background istoo efficient. While there is burst of energy in the background betweenframes 2300 and 2400, there is an increased risk of front end clippingof the utterance starting at frame 2400.

FIG. 9 is also a diagram showing the energy, Etot (dots) of a number offrames of an audio signal, in this case a music signal. The music filefor this illustration has a very noise like start and this causes thenoise estimation to make a wrong decision and allow for an update a bitinto the file (around frame 200). However, with the forced backgroundreduction, it starts to recover at frame 1700 and by frame 2100 thenoise estimate is down to the lowest level for the forced reduction. Asseen from the figure it would not be possible to have the samebackground level reduction with the normal update logic as the input ishigher than the background estimate for most of the frames.

Concluding Remarks

The background estimator described above may be comprised in a SAD, acodec and/or in a device, such as a communication device. Thecommunication device may be a user equipment (UE) in the form of amobile phone, video camera, sound recorder, tablet, desktop, laptop, TVset-top box or home server/home gateway/home access point/home router.The communication device may in some embodiments be a communicationsnetwork device adapted for coding and/or transcoding. Examples of suchcommunications network devices are servers, such as media servers,application servers, routers, gateways and radio base stations. Thecommunication device may also be adapted to be positioned in, i.e. beingembedded in, a vessel, such as a ship, flying drone, airplane and a roadvehicle, such as a car, bus or lorry. Such an embedded device wouldtypically belong to a vehicle telematics unit or vehicle infotainmentsystem.

The steps, functions, procedures, modules, units and/or blocks describedherein may be implemented in hardware using any conventional technology,such as discrete circuit or integrated circuit technology, includingboth general-purpose electronic circuitry and application-specificcircuitry.

Particular examples include one or more suitably configured digitalsignal processors and other known electronic circuits, e.g. discretelogic gates interconnected to perform a specialized function, orApplication Specific Integrated Circuits (ASICs).

Alternatively, at least some of the steps, functions, procedures,modules, units and/or blocks described above may be implemented insoftware such as a computer program for execution by suitable processingcircuitry including one or more processing units. The software could becarried by a carrier, such as an electronic signal, an optical signal, aradio signal, or a computer readable storage medium before and/or duringthe use of the computer program in the network nodes.

The flow diagram or diagrams presented herein may be regarded as acomputer flow diagram or diagrams, when performed by one or moreprocessors. A corresponding apparatus may be defined as a group offunction modules, where each step performed by the processor correspondsto a function module. In this case, the function modules are implementedas a computer program running on the processor.

Examples of processing circuitry includes, but is not limited to, one ormore microprocessors, one or more Digital Signal Processors, DSPs, oneor more Central Processing Units, CPUs, and/or any suitable programmablelogic circuitry such as one or more Field Programmable Gate Arrays,FPGAs, or one or more Programmable Logic Controllers, PLCs. That is, theunits or modules in the arrangements in the different nodes describedabove could be implemented by a combination of analog and digitalcircuits, and/or one or more processors configured with software and/orfirmware, e.g. stored in a memory. One or more of these processors, aswell as the other digital hardware, may be included in a singleapplication-specific integrated circuitry, ASIC, or several processorsand various digital hardware may be distributed among several separatecomponents, whether individually packaged or assembled into asystem-on-a-chip, SoC.

It should also be understood that it may be possible to re-use thegeneral processing capabilities of any conventional device or unit inwhich the proposed technology is implemented. It may also be possible tore-use existing software, e.g. by reprogramming of the existing softwareor by adding new software components.

The embodiments described above are merely given as examples, and itshould be understood that the proposed technology is not limitedthereto. It will be understood by those skilled in the art that variousmodifications, combinations and changes may be made to the embodimentswithout departing from the present scope. In particular, different partsolutions in the different embodiments can be combined in otherconfigurations, where technically possible.

When using the word “comprise” or “comprising” it shall be interpretedas non-limiting, i.e. meaning “consist at least of”.

It should also be noted that in some alternate implementations, thefunctions/acts noted in the blocks may occur out of the order noted inthe flowcharts. For example, two blocks shown in succession may in factbe executed substantially concurrently or the blocks may sometimes beexecuted in the reverse order, depending upon the functionality/actsinvolved. Moreover, the functionality of a given block of the flowchartsand/or block diagrams may be separated into multiple blocks and/or thefunctionality of two or more blocks of the flowcharts and/or blockdiagrams may be at least partially integrated. Finally, other blocks maybe added/inserted between the blocks that are illustrated, and/orblocks/operations may be omitted without departing from the scope ofinventive concepts.

It is to be understood that the choice of interacting units, as well asthe naming of the units within this disclosure are only for exemplifyingpurpose, and nodes suitable to execute any of the methods describedabove may be configured in a plurality of alternative ways in order tobe able to execute the suggested procedure actions.

It should also be noted that the units described in this disclosure areto be regarded as logical entities and not with necessity as separatephysical entities.

Reference to an element in the singular is not intended to mean “one andonly one” unless explicitly so stated, but rather “one or more.” Allstructural and functional equivalents to the elements of theabove-described embodiments that are known to those of ordinary skill inthe art are expressly incorporated herein by reference and are intendedto be encompassed hereby. Moreover, it is not necessary for a device ormethod to address each and every problem sought to be solved by thetechnology disclosed herein, for it to be encompassed hereby.

In some instances herein, detailed descriptions of well-known devices,circuits, and methods are omitted so as not to obscure the descriptionof the disclosed technology with unnecessary detail. All statementsherein reciting principles, aspects, and embodiments of the disclosedtechnology, as well as specific examples thereof, are intended toencompass both structural and functional equivalents thereof.Additionally, it is intended that such equivalents include bothcurrently known equivalents as well as equivalents developed in thefuture, e.g. any elements developed that perform the same function,regardless of structure.

ABBREVIATIONS

-   AMR Adaptive Multi-Rate-   DTX Discontinuous Transmission-   VAD Voice Activity Detector-   3GPP Third Generation Partnership Project-   SID Silence Insertion Descriptor-   SAD Voice Activity Detector-   SNR Signal-to-Noise Ratio-   WB Wide-Band

1. A method by an apparatus, the method comprising: performing by atleast one processor of the apparatus: when a current energy level of anaudio signal segment is higher than a current sub-band noise estimateand no pause is in the audio signal segment, reducing the currentsub-band noise estimate by reducing the current sub-band noise estimateby a defined amount for at least one sub-band of the audio signalsegment.
 2. The method according to claim 1 wherein reducing the currentsub-band noise estimate when the current energy level of the audiosignal segment is higher than the current sub-band noise estimate and nopause is in the audio signal segment comprises reducing the currentsub-band noise estimate by the defined amount for the at least onesub-band of the audio signal segment responsive to the audio signalsegment comprising music, the current energy level of the audio signalsegment being higher than the current sub-band noise estimate, and nopause is in the audio signal segment.
 3. The method according to claim1, wherein no pause is in the audio signal segment when one or both ofthe following is fulfilled: a predefined number of consecutive precedingaudio signal segments have been determined to comprise an active signal;a dynamic of an audio signal comprising the audio signal segment doesnot exceed a signal dynamics threshold.
 4. The method of according toclaim 1 further comprising responsive to the current sub-band noiseestimate satisfying a defined rule, reducing the current sub-band noiseestimate by the defined amount for the at least one sub-band of theaudio signal segment.
 5. The method according to claim 4 wherein thecurrent sub-band noise estimate satisfies the defined rule when thecurrent sub-band noise estimate exceeds a predefined value.
 6. Themethod according to claim 4 wherein the current sub-band noise estimatesatisfies the defined rule when an energy level of the audio signalsegment is less than a threshold level higher than a long term minimumenergy level (It_min) over a plurality of preceding audio signalsegments.
 7. The method according to claim 6, wherein the energy levelof the audio signal segment is less than the threshold level higher thanIt_min is based on information derived from an input audio signal andnot based on use of information from a sound activity detector.
 8. Themethod according to claim 1, wherein reducing the current sub-band noiseestimate by the defined amount comprises: determining a step size toreduce the current sub-band noise estimate; and reducing the currentsub-band noise estimate by the step size.
 9. An apparatus comprising: atleast one processor configured to perform operations comprising: when acurrent energy level of an audio signal segment is higher than a currentsub-band noise estimate and no pause is in the audio signal segment,reducing the current sub-band noise estimate by reducing the currentsub-band noise estimate by a defined amount for at least one sub-band ofthe audio signal segment.
 10. The apparatus according to claim 9 whereinreducing the current sub-band noise estimate when the current energylevel of the audio signal segment is higher than the current sub-bandnoise estimate and no pause is in the audio signal segment comprisesreducing the current sub-band noise estimate by the defined amount forthe at least one sub-band of the audio signal segment responsive to theaudio signal segment comprising music, the current energy level of theaudio signal segment being higher than the current sub-band noiseestimate, and no pause is in the audio signal segment.
 11. The apparatusaccording to claim 9, wherein no pause is considered to in the audiosignal segment when one or both of the following is fulfilled: apredefined number of consecutive preceding audio signal segments havebeen determined to comprise an active signal; a dynamic of an audiosignal comprising the audio signal segment does not exceed a signaldynamics threshold.
 12. The apparatus according to claim 9 wherein theat least one processor configured to perform further operationscomprising: responsive to the current sub-band noise estimate satisfyinga defined rule, reducing the current sub-band noise estimate by thedefined amount for the at least one sub-band of the audio signalsegment.
 13. The apparatus according to claim 12, wherein the currentsub-band noise estimate satisfies the defined rule when the currentsub-band noise estimate exceeds a predefined value.
 14. The apparatusaccording to claim 12, wherein the at least one processor performsfurther operations comprising setting a flag responsive to the currentsub-band noise estimate satisfying the defined rule to indicate that theenergy level of the audio signal segment is less than the thresholdlevel higher than It_min.
 15. The apparatus according to claim 14,wherein the energy level of the audio signal segment is determined to beless than the threshold level higher than It_min based on informationderived from an input audio signal, and not based on use of informationfrom a sound activity detector.
 16. The apparatus according to claim 12,wherein in reducing the current sub-band noise estimate responsive tothe current sub-band noise estimate satisfying the defined rule, the atleast one processor performs operations comprising: determining a stepsize to reduce the current sub-band noise estimate; and reducing thecurrent sub-band noise estimate by the step size.
 17. A computer programproduct comprising a non-transitory computer readable storage mediumstoring instructions which, when executed on at least one processor,cause the at least one processor to perform operations comprising: whena current energy level of an audio signal segment is higher than acurrent sub-band noise estimate and no pause is detected in the audiosignal segment, reducing the current sub-band noise estimate by reducingthe current sub-band noise estimate by a defined amount for at least onesub-band of the audio signal segment.
 18. The computer program productof claim 17 wherein reducing the current sub-band noise estimate whenthe current energy level of the audio signal segment is higher than thecurrent sub-band noise estimate and no pause is detected in the audiosignal segment comprises reducing the current sub-band noise estimate bythe defined amount for the at least one sub-band of the audio signalsegment responsive to the audio signal segment comprising music, thecurrent energy level of the audio signal being higher than the currentsub-band noise estimate, and no pause is detected in the audio signalsegment.
 19. The computer program product of claim 17 wherein no pauseis considered to in the audio signal segment when one or both of thefollowing is fulfilled: a predefined number of consecutive precedingaudio signal segments have been determined to comprise an active signal;a dynamic of an audio signal comprising the audio signal segment doesnot exceed a signal dynamics threshold.
 20. The computer program productof claim 17 wherein the non-transitory computer readable storage mediumstores further instructions which, when executed on the at least oneprocessor, cause the at least one processor to perform furtheroperations comprising responsive to the current sub-band noise estimatesatisfying a defined rule, reducing the current sub-band noise estimateby the defined amount for the at least one sub-band of the audio signalsegment.